Sheet molding compound flow field plate, bipolar plate and fuel cell

ABSTRACT

This invention provides a highly electrically conductive sheet molding compound (SMC) composition and a fuel cell flow field plate or bipolar plate made from such a composition. The composition comprises a top sheet, a bottom sheet, and a resin mixture sandwiched between the top sheet and the bottom sheet. At least one of the top sheet and bottom sheet comprises a flexible graphite sheet, which has a substantially planar outer surface having formed therein a fluid flow channel. Further, the resin mixture comprises a thermoset resin and a conductive filler present in a sufficient quantity to render the flow field plate electrically conductive enough to be a current collector (preferably with a conductivity no less than 100 S/cm). Preferably, both the top and bottom surfaces are flexible graphite sheets, each having a substantially planar outer surface having therein a fluid flow channel formed by embossing. These two flexible graphite sheets are well-bonded by the middle resin mixture layer to form a highly conductive bipolar plate, which is particularly useful for proton exchange membrane fuel cell applications.

The present invention is based on the research results of a project supported by the NSF SBIR-STTR Program. The US government has certain rights on this invention.

FIELD OF THE INVENTION

The present invention relates to a sheet molding compound (SMC) for use in a fuel cell bipolar plate or flow field plate. In particular, it relates to a flexible graphite-based, highly electrically conductive SMC for use as a flow field plate or bipolar plate in a proton exchange membrane fuel cell.

BACKGROUND OF THE INVENTION

A fuel cell converts chemical energy into electrical energy and some thermal energy by means of a chemical reaction between a fuel (e.g., hydrogen gas or a hydrogen-containing fluid) and an oxidant (e.g., oxygen). A proton exchange membrane (PEM) fuel cell uses hydrogen or hydrogen-rich reformed gases as the fuel, a direct-methanol fuel cell (DMFC) uses methanol-water solution as the fuel, and a direct ethanol fuel cell (DEFC) uses ethanol-water solution as the fuel, etc. These types of fuel cells that require utilization of a PEM layer as a proton transport electrolyte are collectively referred to as PEM-type fuel cells.

A PEM-type fuel cell is typically composed of a seven-layered structure, including (a) a central PEM electrolyte layer for proton transport; (b) two electro-catalyst layers on the two opposite primary surfaces of the electrolyte membrane; (c) two fuel or gas diffusion electrodes (GDEs, hereinafter also referred to as diffusers) or backing layers stacked on the corresponding electro-catalyst layers (each GDE comprising porous carbon paper or cloth through which reactants and reaction products diffuse in and out of the cell); and (d) two flow field plates (or a bi-polar plate) stacked on the GDEs. The flow field plates are typically made of graphite, metal, or conducting composite materials, which also serve as current collectors. Gas-guiding channels are defined on a GDE facing a flow field plate or, more typically, on a flow field plate surface facing a GDE. Reactants (e.g., H₂ or methanol solution) and reaction products (e.g., CO₂ at the anode of a DMFC, and water at the cathode side) are guided to flow into or out of the cell through the flow field plates. The configuration mentioned above forms a basic fuel cell unit. Conventionally, a fuel cell stack comprises a number of basic fuel cell units that are electrically connected in series to provide a desired output voltage. If desired, cooling channels and humidifying plates may be added to assist in the operation of a fuel cell stack.

In one common practice, a fuel flow field plate and an oxidant gas flow field plate are separately made and then assembled together to form a bipolar plate (one side of a bipolar plate serving as a negative terminal and the other side as a positive terminal, hence the name). In some cases, an additional separator is sandwiched between the two flow field plates to form a bipolar plate. It would be highly advantageous if the flow filed plates and the separator can be mass-produced into an integrated bipolar plate assembly. This could significantly reduce the overall fuel cell production costs and reduce contact ohmic losses across constituent plate interfaces. The bipolar plate is known to significantly impact the performance, durability, and cost of a fuel cell system. The bipolar plate, which is typically machined from graphite, is one of the most costly components in a PEM fuel cell.

Fluid flow field plates have open-faced channels formed in one or both opposing major surfaces for distributing reactants to the gas diffuser plates (the anode and cathode backing layers, typically made of carbon paper or fabric). The open-faced channels also provide passages for the removal of reaction products and depleted reactant streams. Optionally, a bipolar plate may have coolant channels to manage the fuel cell temperature. A bipolar plate should have the following desirable characteristics: high electrical conductivity (e.g., preferably having a conductivity no less than 100 S/cm), low permeability to fuel or oxidant fluids, good corrosion resistance, and good structural integrity.

Conventional methods of fabricating fluid flow field plates require the engraving or milling of flow channels into the surface of rigid plates formed of a metal, graphite, or carbon-resin composite. These methods of fabrication place significant restrictions on the minimum achievable fuel cell thickness due to the machining process, plate permeability, and required mechanical properties. Further, such plates are expensive due to high machining costs. The machining of channels into the graphite plate surfaces causes significant tool wear and requires significant processing times.

Alternatively, fluid flow field plates can be made by a lamination process (e.g., U.S. Pat. No. 5,300,370, issued Apr. 5, 1994), wherein an electrically conductive, fluid impermeable separator layer and an electrically conductive stencil layer are consolidated to form one open-faced channel. Presumably, two conductive stencil layers and one separator layer may be laminated to form a bipolar plate. It is often difficult and time-consuming to properly position and align the separator and stencil layers. Die-cutting of stencil layers require a minimum layer thickness, which limits the extent to which fuel cell stack thickness can be reduced. Such laminated fluid flow field assemblies tend to have higher manufacturing costs than integrated plates, due to the number of manufacturing steps associated with forming and consolidating the separate layers. They are also prone to delamination due to poor interfacial adhesion and vastly different coefficients of thermal expansion between a stencil layer (typically a metal) and a separator layer.

A variety of composite bipolar plates have been developed, which are mostly made by compression molding of polymer matrices (thermoplastic or thermoset resins) filled with conductive particles such as graphite powders or fibers. Because most polymers have extremely low electronic conductivity, excessive conductive fillers have to be incorporated, resulting in an extremely high viscosity of the filled polymer melt or liquid resin and, hence, making it very difficult to process. Bi-polar plates for use in PEM fuel cells constructed of graphite powder/fiber filled resin composite materials and having gas flow channels are reviewed by Wilson, et al (U.S. Pat. No. 6,248,467, Jun. 19, 2001). Injection-molded composite-based bipolar plates are disclosed by Saito, et al. (U.S. Pat. Nos. 6,881,512, Apr. 19, 2005 and U.S. Pat. No. 6,939,638, Sep. 6, 2005). These thermoplastic or thermoset composites exhibit a bulk conductivity significantly lower than 100 S/cm (the US Department of Energy target value), typically not much higher than 10 S/cm.

Besmann, et al. disclosed a carbon/carbon composite-based bipolar plate (U.S. Pat. No. 6,171,720 (Jan. 9, 2001) and U.S. Pat. No. 6,037,073 (Mar. 14, 2000)). The manufacture process consists of multiple steps, including production of a carbon fiber/phenolic resin preform via slurry molding, followed by a compression-molding step. The molded part is then pyrolyzed at a high temperature (1,500° C.-2,500° C.) to obtain a highly porous carbon/carbon composite. This is followed by chemical vapor infiltration (CVI) of a carbon matrix into this porous structure. It is well-known that CVI is a very time-consuming and energy-intensive process and the resulting carbon/carbon composite, although exhibiting a high electrical conductivity, is very expensive.

Instead of using pyrolyzation and CVI to produce carbon/carbon composites, Huang, et al. (U.S. Patent Application Pub. No. 2004/0229993, Nov. 18, 2004) discloses a process to produce a thermoplastic composite with a high graphite loading. First, polymer fibers, such as thermotropic liquid crystalline polymers or polyester, reinforcing fibers such as glass fibers, and graphite particles are combined with water to form a slurry. The slurry is pumped and deposited onto a sieve screen. The sieve screen serves the function of separating the water from the mixture of polymer fibers, glass fibers and graphite. The mixture forms a wet-lay sheet which is placed in an oven. Upon heating to a temperature sufficient to melt the polymer fibers, the wet-lay sheet is allowed to cool and have the polymer material solidify. Upon solidification, the wet-lay sheet takes the form of a sheet material with reinforcement glass fibers held together by globules of thermoplastic material, and graphite particles adhered to the sheet material by the thermoplastic material. Several of these sheets are then stacked, preferably with additional graphite powder interspersed between sheets, and compression-molded in a hot press. After application of heat and pressure in the press, one or more formed bipolar plates are obtained, where the bipolar plates are a composite of glass fibers, thermoplastic matrix and graphite particles. Clearly, this is also a tedious process which is not amenable to mass production.

Alternatively, fluid flow field plates can be made from an electrically conductive, substantially fluid impermeable material that is sufficiently compressible or moldable so as to permit embossing. Flexible graphite sheet is generally suitable for this purpose because it is relatively impervious to typical fuel cell reactants and coolants and thus is capable of isolating the fuel, oxidant, and coolant fluid streams from each other. It is also compressible and embossing processes may be used to form channels in one or both major surfaces. The “flexible graphite” is the exfoliated reaction product of rapidly heated natural graphite particles which have been treated with an agent that intercalates into the crystal structure of the graphite to expand the intercalated particles at least 80 or more times (up to 1000 times) in the direction perpendicular to the carbon layers in the crystal structure. The exfoliated graphite particles are vermiform in appearance, and are therefore commonly referred to as worms. The worms may be compressed together into flexible sheets which, unlike the original graphite flakes, can be formed and cut into various shapes. These thin sheets (foils or films) are hereinafter referred to as flexible graphite. Flexible graphite can be wound up on a drum to form a roll of thin film, just like a roll of thin plastic film or paper.

Although highly conductive, flexible graphite sheets by themselves do not have sufficient stiffness and must be supported by a core layer or impregnated with a resin. For example, U.S. Pat. No. 5,527,363 (Jun. 18, 1996) discloses a fluid flow field plate comprising a metal sheet interposed between two flexible graphite (FG) sheets having flow channels embossed on a major surface thereof. These FG-metal-FG laminates are also subject to the delamination or blistering problem, which could weaken the plate and may make it more fluid permeable. Delamination or blistering can also cause surface defects that may affect the flow channels on the plate. These problems may be difficult to detect during fabrication and may only emerge at a later date. In particular, thermal cycling between frozen and thawed conditions as are likely to be encountered in an automobile application of the fuel cell, often results in delamination between a flexible graphite layer and the metal layer. Alternatively, Mercuri, et al. (U.S. Pat. No. 5,885,728, Mar. 23, 1999) discloses a flexible graphite sheet having embedded fibers extending from its surface into the sheet to increase the resin permeability of the sheet for the preparation of a resin-impregnated flexible graphite bipolar plate. The step of adding ceramic fibers significantly increases the process complexity and cost.

The flow field plate should be constructed from inexpensive starting materials, materials that are easily formed into any plate configuration, preferably using a continuous molding process, and materials that are corrosion resistant in low temperature fuel cells and that do not require further processing such as high temperature pyrolization treatments. Any laminated or multi-layer plate should have adequate bonding between layers to ensure structural integrity and reduced contact resistance (reduced power loss due to joule heating).

Accordingly, an object of the present invention is to provide a new and improved fuel cell flow field plate or a bipolar plate that is a well-integrated sheet molding compound (SMC) component made by using a fast and cost-effective process. The process can be automated and adaptable for mass production. In particular, the bipolar plate has the flexible graphite serving as the top and bottom sheets, which are bonded by an electrically conductive resin mixture. The resulting fuel cell system is highly conductive and well-suited to being a current collector.

Another object of the present invention is to provide a fuel cell flow field plate that is a sheet molding compound composed of at least a flexible graphite sheet and an electrically conductive resin mixture-based separator layer that are well-bonded into a flow field plate, wherein the flexible graphite sheet has a surface flow field channel.

SUMMARY OF THE INVENTION

One embodiment of the prevent invention is a sheet molding compound (SMC) composition, particularly for use as a fuel cell flow field plate or bipolar plate. The SMC composition comprises a top sheet, a bottom sheet, and a resin mixture sandwiched between the top sheet and the bottom sheet. At least one of the top sheet and bottom sheet comprises a flexible graphite sheet. The flexible graphite sheet has a planar outer surface having formed therein a fluid flow channel. The resin mixture comprises a thermoset resin and a conductive filler present in a sufficient quantity to render the SMC composition electrically conductive enough to be a current collector material. When the resin is cured or solidified, the two sheets are well bonded by the resin to provide good structural integrity to the resulting “laminated” structure.

When both the top and bottom sheets are flexible graphite, bonded by an electrically conductive resin mixture, the resulting three-layer plate can be used as a bipolar plate that is interposed between two fuel cell units. In this case, each flexible graphite sheet has a substantially planar outer surface having fluid flow channels molded therein. These flow channels are preferably created through embossing during or after the SMC is made on a continuous basis.

If only one sheet (say, the top sheet) is flexible graphite and the bottom sheet is a sheet of plastic material (plastic film), the flexible graphite sheet and the plastic sheet may be laminated initially into a three-layer SMC plate. A mold release agent may be used between the plastic sheet and the resin mixture layer to facilitate later separation of the plastic sheet from the resin mixture-bonded flexible graphite plate. Embossing or matched-mold pressing is carried out before, during, and/or after resin curing to produce flow channels on the outer surface of the flexible graphite sheet. The plastic sheet or film is then peeled off, leaving behind a two-layer plate that can be used as a flow field plate.

Another embodiment of the present invention is a sheet molding compound composition, comprising a top sheet, a bottom sheet, and a resin mixture sandwiched between the top sheet and the bottom sheet. The top sheet and/or the bottom sheet comprises a flexible graphite sheet. The resin mixture comprises a thermoset resin and a conductive filler present in a sufficient quantity to render the resin mixture electrically conductive with a bulk conductivity of the resin mixture (after curing) no less than 10 S/cm (preferably no less than 50 S/cm). The resulting three-layer SMC composition (after resin curing or molding) has a conductivity typically above 100 S/cm, which is the US Department of Energy (DOE) target for composite bipolar plates. In many cases, the SMC conductivity exceeds 200 S/cm and, in some cases, exceeds 250 S/cm, which are quite impressive.

In the aforementioned SMCs, the conductive filler comprises a conductive material selected from the group consisting of carbon fibers, metal fibers, carbon nano-tubes, graphitic nano-fibers, nano-scaled graphene plates, carbon blacks, metal particles, and combinations thereof The conductive material being present in an amount of at least about 3% by weight (preferably at least 20% by weight), based on total weight of the resin mixture. Preferably, the SMC composition as defined above has a resin mixture having a thickness no greater than 1/15 of the sum of the top sheet thickness and the bottom sheet thickness.

BRIEF DESCRIPTION OF THE DRAWING

FIG. 1: A sectional view of a prior art PEM fuel cell consisting of a membrane electrode assembly (MEA) sandwiched between two flow field plates 21, 23.

FIG. 2: A sectional view of a fuel cell stack consisting of two fuel cell units connected in series through a bipolar plate 19.

FIG. 3: A sectional view of (a) a bipolar plate consisting of a top flexible graphite layer, a bottom flexible graphite layer, and a core resin-mixture layer; (b) a flow field plate consisting of a top flexible graphite layer, a core resin mixture layer, and a plastic film as a tentative bottom layer; and (c) a flow field plate with the plastic film peeled off.

FIG. 4: (a) Schematic of a roll-to-roll process for preparing a highly conductive sheet molding compound (SMC); (b) schematic of a process for fabricating SMC-based flow field plates or bipolar plates with the surface flow channels being generated via in-line embossing or matched-mold pressing.

FIG. 5: (a) Schematic of two matting flow field plates each with half of the coolant channels; (b) the two plates, after being molded with the thermoset resin cured, are combined to form a bi-polar plate with coolant channels.

FIG. 6: (a) Schematic of two matting SMC laminates (prior to being fully cured) being molded in a matched-mold pressing process with molding pins being inserted to produce coolant channels; (b) the resulting integral bipolar plate with built-in coolant channels.

FIG. 7: A sectional view of stacked fuel cells using a series of bipolar plates in accordance with the present invention.

FIG. 8: SMC bipolar plate conductivity as a function of top layer-to-resin mixture layer thickness ratio for the first set of examples.

DETAILED DESCRIPTION OF THE INVENTION

A prior art fuel cell, as shown in FIG. 1, typically comprises a membrane electrode assembly 8, which comprises a proton exchange membrane 14 (PEM), an anode backing layer 10 connected to one face of the PEM 14, and a cathode backing layer 12 connected to the opposite face of PEM 14. Anode backing layer 10 is also referred to as a fluid diffusion layer or diffuser, typically made of carbon paper or carbon cloth. A platinum/ruthenium electro-catalytic film 16 is positioned at the interface between the anode backing layer and PEM 14 for promoting oxidation of the methanol fuel. Similarly, at the cathode side, there are a backing layer or diffuser 12 (e.g., carbon paper or carbon cloth) and a platinum electro-catalytic film 18 positioned at the interface between the cathode backing layer and PEM 14 for promoting reduction of the oxidant.

In practice, the proton exchange membrane in a PEM-based fuel cell is typically coated on both sides with a catalyst (e.g., Pt/Ru or Pt) to form a catalyst-coated membrane 9 (CCM). The CCM layer 9 is then sandwiched between an anode backing layer 10 (diffuser) and a cathode backing layer 12 (diffuser). The resulting five-layer assembly is called a membrane electrode assembly 8 (MEA). Although some fuel cell workers sometimes refer to CCM as a MEA, we prefer to take the MEA to mean a five-layer configuration: anode backing layer, anode catalyst layer, PEM, cathode catalyst layer, and cathode backing layer.

The fuel cell also comprises a pair of fluid distribution plates (also referred to as fluid flow field plates) 21 and 23, which are positioned on opposite sides of membrane electrode assembly 8. Plate 21, which serves as a fuel distribution plate, is shaped to define fuel flow channels 22 facing towards anode diffuser 10. Channels 22 are designed to uniformly deliver the fuel to the diffuser, which transports the fuel to the anode catalyst layer 16. An input port and an output port (not shown), being in fluid communication with channels 22, may also be provided in flow field plate 21 so that carbon dioxide (in a DMFC) can be withdrawn from channels 22.

Flow field plate 23 is shaped to include fluid channels 24 for passage of a quantity of gaseous oxygen (or air). An input port and an output port (not shown) are provided in plate 23, which are in fluid communication with channels 24 so that oxygen (or air) can be transported through the input port to the cathode diffuser 12 and cathode catalyst layer 18, and water and excess oxygen (or air) can be withdrawn from channels 24 through the output port. Plate 23 is electrically conductive and in electrical contact with cathode diffuser 12. It can be used as a uni-polar plate (the positive terminal of the electrical current generated by the fuel cell unit) or as a part of a bi-polar plate (if integrated with fuel flow field plate 21). Shown in FIG. 2 is a fuel cell stack that consists of two fuel cell units. On the two opposite sides of the stack are two separate flow field plates 21 a, 23 a. Between the two MEAs (8 a and 8 b) is a bipolar plate 19, which can be viewed as two flow field plates integrated into one single component.

In the manufacture of fiber reinforced resin composite products, conventional (prior art) sheet molding compounds (SMCs) are frequently used which consist of a mixture of a viscous uncured thermosetting resin and chopped fibers, such as glass fibers. In most cases the resin and chopped fibers are sandwiched between films of plastic material to form a laminated structure which is wound in coiled form. The laminate is stored under conditions which will not result in final curing of the resin. At the time of use, the laminate is uncoiled and cut to the desired size and shape for the molding operation. As the resin which is employed to provide the sheet molding compound is relatively viscous, specific procedures must be employed to provide a thorough impregnation of fibers with the resin. Impregnation can be achieved by passing the laminated structure between cooperating rolls or flexing the laminate in concave and convex shapes. These prior art SMC composites do not have a sufficient electrical conductivity for flow field plate or bipolar plate applications.

The present invention provides a highly conductive sheet molding compound (SMC) composition and a fuel cell flow field plate or bipolar plate made from this SMC composition. The SMC-based bipolar plate, schematically shown in FIG. 3(a), comprises a top sheet 71, a bottom sheet 73, and a resin mixture 75 sandwiched between the top sheet and the bottom sheet.

At least one of the top sheet and the bottom sheet comprises a flexible graphite sheet. The flexible graphite sheet (e.g., the top sheet 71) has a planar outer surface 77 having formed therein a fluid flow channel 79. The resin mixture 75 comprises a thermoset resin (with or without a catalyst) and a conductive filler present in a sufficient quantity to render the SMC composition electrically conductive enough to be a current collector material (with a conductivity of the SMC preferably no less than 100 S/cm). When the resin is cured or solidified, the two sheets 71,73 are well bonded by the resin to provide good structural integrity to the resulting “laminated” structure. The thermoset resin can be any resin which, upon exposure to heat or high energy radiation (e.g., electron beam), becomes cured (e.g., forming a cross-linked network). The thermoset resin may be advantageously selected from the group consisting of unsaturated polyester resins, vinyl esters, epoxies, phenolic resins, polyimide resins, bismaleimide resins, polyurethane resins, and combinations thereof.

In one preferred embodiment (FIG. 3(a)), when both the top and bottom sheets are flexible graphite and are bonded by an electrically conductive resin mixture, the resulting three-layer plate can be used as a bipolar plate that is interposed between two fuel cell units. In this case, each flexible graphite sheet has a substantially planar outer surface (e.g., surface 77 on the top sheet 71 and surface 81 on the bottom sheet 73) having fluid flow channels (e.g., channel 79 on the top sheet and 83 on the bottom sheet) molded therein. These flow channels are preferably created through embossing during or after the SMC plate is made on a continuous basis.

The conductive filler in the resin mixture may be selected from small-sized particles (preferably smaller than 10 μm and more preferably smaller than 1 μm) such as a carbon black, graphite particle, nano-scaled graphene plate, graphitic nano-fiber, metal particle, or a combination thereof. When a thicker resin mixture layer (also hereinafter referred to as the core layer) is allowed or desired, carbon or graphite fibers (fiber diameter typically greater than 12 μm) may also be used, alone or in conjunction with the aforementioned small-sized particles. A second thermoset resin or a thermoplastic may be used to adjust the mixture viscosity and to assist in bonding the filler particles together. Although not necessarily preferred, a quantity of other types of reinforcement fiber, such as glass fiber or polymer fiber, may be added to impart additional structural integrity to the resin mixture layer and that of the SMC.

The type and proportion of the conductive filler are preferably chosen in such a way that the bulk conductivity of the resulting resin mixture is greater than 10 S/cm, further preferably greater than 50 S/cm, and most preferably greater than 100 S/cm. Typically, when the conductive filler proportion in the resin mixture is between 3% and 20% by weight (based on the total weight of the resin mixture), the bulk conductivity of the resin mixture exceeds 10 S/cm, up to approximately 35 S/cm, depending on the filler type. When the proportion is between approximately 20% and 45%, the resin matrix conductivity exceeds 50 S/cm. When the proportion is greater than 45%, the resin matrix conductivity exceeds 100 S/cm. This has led to SMC plates having an overall conductivity mostly greater than 100 S/cm, typically greater than 200 S/cm, and, in many cases, even greater 250 S/cm, far exceeding the US Department of Energy conductivity target (100 S/cm) for composite bipolar plates.

If only one sheet (say, the top sheet 71 a) is flexible graphite and the bottom sheet is a sheet of plastic material (plastic film 73 a), the flexible graphite sheet and the plastic sheet may be laminated initially into a three-layer SMC structure (FIG. 3(b)). A mold release agent may be used between the plastic sheet and the resin mixture layer to facilitate later separation of the plastic sheet from the resin mixture-bonded flexible graphite plate. Embossing or matched-mold pressing is carried out before, during, and/or after resin curing to produce flow channels 79 a on the outer surface 77 a of the flexible graphite sheet 71 a. The plastic sheet or film 73 a is then peeled off, leaving behind a two-layer plate (FIG. 3(c)) that can be used as a flow field plate.

In one embodiment of the present invention, the top sheet is a flexible graphite foil, but the bottom sheet can be an electrically conductive film or foil, such as a carbon paper, carbon or graphite fabric, conductive polymer film, or metal foil. This will also make a good bipolar plate. In another preferred embodiment, both the top and bottom sheets can be selected from a carbon paper, carbon/graphite fabric, carbon/graphite fiber-containing mat, conductive polymer film, thin metal foil and/or flexible graphite. In theses cases, a portion of the thermoset resin in the resin mixture of the core layer can permeate into the top or bottom layer to further enhance the structural integrity of the resulting laminate.

The overall conductivity of a two-layer flow field plate or a three-layer bipolar plate also depends upon the relative thickness of the resin matrix layer (or core layer) with respect to the total thickness of the flexible graphite sheets. Since the flexible graphite is highly conductive (typically with a conductivity greater than 300 S/cm) and the resin matrix layer is typically lower than flexible graphite in conductivity, the resin matrix layer should be made as thin as possible to achieve a maximum electronic conductivity. When the resin matrix conductivity is relatively low (e.g., 10 S/cm), a ratio of core layer thickness-to-total flexible graphite thickness typically is as small as 1/15 in order to achieve a bipolar plate conductivity of 100 S/cm or greater. With both of the top and bottom layers being each 0.3 mm (300 μm) thick, the resin mixture layer is thinner than 40 μm. In order to obtain a bipolar plate conductivity of 200 S/cm, the resin mixture layer has to be lower than 10 μm. However, a certain minimum core layer thickness may be desired to obtain a desired level of mechanical stiffness or strength of the bipolar plate.

By contrast, if the resin matrix conductivity is higher (e.g., 50 S/cm), a much higher ratio of core layer thickness-to-total flexible graphite thickness can be used in order to achieve a bipolar plate conductivity of 100 S/cm. In this case, the resin mixture layer can be almost as thick as a flexible graphite sheet. More advantageously, when each flexible graphite sheet is approximately 300 μm thick and when the resin mixture layer is 60 μm or thinner, a bipolar plate conductivity as high as 200 S/cm can be achieved. A resin matrix layer of approximately 60 μm can be prepared quite easily. The above observations will be further illustrated when examples are given at a later section.

Electrically conductive and corrosion resistant materials are useful for other applications (e.g., battery electrodes) than fuel cells. Hence, the presently invented SMCs have a wide range of applications. Thus, another embodiment of the present invention is a sheet molding compound composition, comprising a top sheet, a bottom sheet, and a resin mixture sandwiched between the top sheet and the bottom sheet. The top sheet and/or the bottom sheet comprises a flexible graphite sheet. The resin mixture comprises a thermoset resin and a conductive filler present in a sufficient quantity to render the resin mixture electrically conductive with a bulk conductivity of the resin mixture no less than 10 S/cm (preferably no less than 50 S/cm). The resulting three-layer SMC composition, upon completion of resin curing to make a SMC product, has a conductivity mostly above 100 S/cm, typically above 200 S/cm, and, in several cases, above 250 S/cm.

As indicated earlier, the conducting filler material may be selected from carbon fibers, metal fibers, metal particles (preferably nano-scaled), carbon nano-tubes (CNTs), graphitic nano-fibers (GNFs), nano-scaled graphene plates, carbon blacks, or a combination thereof. Individual nano-scaled graphite planes (individual graphene sheets) and stacks of multiple nano-scaled graphene sheets are collectively called nano-sized graphene plates (NGPs). The structures of these materials may be best visualized by making a longitudinal scission on the single-wall or multi-wall of a nano-tube along its tube axis direction and then flattening up the resulting sheet or plate. These nano materials have strength, stiffness, and electrical conductivity that are comparable to those of carbon nano-tubes, but NGPs can be mass-produced at lower costs. They can be produced by reducing the expanded graphite particles to much smaller sizes (100 nanometers or smaller). The preparation of other nano-scaled carbon-based materials, including CNTs, GNFs, and carbon black, is well-known in the art. They are all commercially available, along with nano-scaled metal particles. These nano-scaled, electrically conductive filler materials are preferred conductive filler ingredients for use in making the presently invented SMCs. It may be further noted that CNTs, GNFs, and NGPs are known to be capable of imparting high strength and stiffness to a resin matrix. They are ideally suited for the present applications.

Referring to FIG. 4(a) as an example, the preparation of a flexible graphite SMC composition may begin with continuously or intermittently feeding (uncoiling) a thin flexible graphite sheet 34 from a winding drum 32. The surface of the flexible graphite sheet 34 may be coated (or pre-coated) with a desired layer 36 of an uncured thermoset resin via a number of prior art coating techniques (e.g., spraying, printing, spin-coating, or, simply, brushing). A powder dispenser 38 is then operated to deposit a desired amount of a conductive filler 40 (or conductive filler plus some resin) onto the top surface of the thermoset resin layer 36 while the flexible graphite sheet is being driven forward to the right. A leveling device 42 (e.g., a scraping blade) is used to form a uniform-thickness layer 39 of a resin-filler premix. Concurrently, another flexible graphite sheet 46, also coated or pre-coated with a thermoset resin layer 48 (with same or different composition), is similarly fed from a drum 44 in such a way that the resin layer 48 comes in contact with the premix 39 to form a three-layer pre-SMC composition. This laminated pre-SMC composition is then fed through the gap between a pair of rollers 47 a, 47 b to compress the composition 50 a. A series of rollers (e.g., between 47 a, 47 b and 49 a, 49 b) are used to assist in mixing of the resin with the conductive filler. Specifically, impregnation or mixing of the filler particles/fibers with the resin can be achieved by passing the laminated structure 50 a between cooperating rolls or flexing the laminate in concave and convex shapes to obtain a well-mixed SMC 50 b, which can be wound up on a roller 51. The SMC may be stored under conditions which will not result in final curing of the resin. A catalyst inhibitor may be used to extend the shelf or storage life of the SMC without premature curing. When a flow field plate or bipolar plate is needed, the SMC is uncoiled and cut to the desired size and shape for the molding operation. Compression molding or hot pressing may be used to create flow channels on the outer surfaces of the plate while the thermoset resin is being cured and hardened.

Alternatively or preferably, as schematically shown in FIG. 4(b), a continuous sheet of SMC is fabricated in a procedure similar to that in FIG. 4(a). Heating means may be used to advance the cure reaction of the thermoset resin (e.g., in a heating zone indicated by a phantom box of FIG. 4(b)) to achieve a desired degree of curing before the SMC is embossed or matched-die molded between a pair of embossing tools 11 a, 11 b or matting mold platens to create the desired flow field channels. These tools or mold platens may also be heated. As the laminated sheet (50 a or 50 b) continues to move forward, another portion of the sheet is embossed or molded. This is a continuous process that is suitable for cost-effective mass production of flow field plates or bipolar plates that are highly conductive.

If one of the flexible sheets (either 34 or 46) is a plastic film, this film may be peeled off after resin is cured to obtain a flow field plate (e.g., FIG. 3(c). If coolant channels are needed, they can be created during the SMC molding process in several ways. For instance, during the flow field plate molding process, the mold surface may be shaped to produce a part of a channel groove (e.g., 52 a in FIG. 5(a)). Two matting flow field plates may then be positioned together to form a bipolar plate 54 (FIG. 5(b)) having coolant channels (e.g., 52).

Preferably, coolant channels are built into a bipolar plate when it is molded. For instance, as schematically shown in FIG. 6(a), two uncured or partially cured bi-layer SMC plates (with the plastic film peeled off, leaving behind a resin mixture layer 63 a or 63 b and flexible graphite layer 65 a or 65 b) may be molded between a pair of matched molds (61 a, 61 b) and a number of molding pins 67. These pins, coated with a mold release agent, may be pulled out of the SMC structure to obtain an integral bipolar plate 54 (FIG. 6(b)) with built-in coolant channels 67 a. Optionally, coolant channels may be fitted with connectors, preferably before the resin matrix material is solidified. FIG. 7 shows back-to-back flow field plates that are fabricated as one monolithic component 54, with coolant channels 52 formed as complete channels within the component, as well as reactant channels 60 & 62. The two outer surfaces of bipolar plate 54 are stacked against respective diffuser layers 56,58 (preferably made of carbon paper), which are in turn connected to catalyst-coated membrane (e.g., 70).

The present invention also provides a fuel cell or a stack of fuel cells that comprises a highly conductive flow field plate or bipolar plate component as defined in any of the aforementioned preferred embodiments. The resulting fuel cell system is of lower costs (due to their amenability to mass production) and better performance (due to lower contact resistance and internal resistance and, hence, higher voltage).

Conductivity measurements can be made by using the four-point probe method on small-sized plate samples. Table 1 summarizes the parameters and properties of 28 samples prepared in the present study. The results show that the core layer (resin mixture) composition and thickness have a profound influence to the conductivity of the resulting SMC bipolar plates. The thinner the core layer thickness, the higher the plate conductivity. Most of the SMC samples exhibit very impressive electronic conductivity. TABLE 1 Properties of SMC bipolar plates (flexible graphite resistivity = 0.00333 Ω-cm). Core layer resin mixture Top layer Core layer Core Plate Sample composition thickness resistivity thickness conductivity No. (Weight %) I₁ (cm) ρ₂ (Ω-cm) I₂ (μm) σ (S/cm) 1 65% Ep, 35% Ag 0.03 0.10 1.3 282 2 65% Ep, 25% Ag, 10% NGP 0.03 0.11 3.2 260 3 65% Ep, 25% Ag, 10% GNF 0.03 0.12 12 191 4 65% Ep, 34% Ag, 1% CNT 0.03 0.11 31 124 5 65% Ep, 20% CB, 15% NGP 0.03 0.13 55 87 6 65% Ep, 35% GP 0.03 0.11 78 69 7 65% Ep, 25% GP, 10% CF 0.03 0.12 120 51 8 65% Ep, 30% GP, 5% GL 0.03 0.14 220 34 9 65% Ep, 25% GP, 10% CF 0.03 0.12 310 27 10 35% Ep, 35% Ag, 30% NGP 0.03 0.010 3.7 297 11 35% Ep, 55% Ag, 10% NGP 0.03 0.011 5.6 294 12 35% Ep, 55% Ag, 10% GNF 0.03 0.012 15 286 13 35% Ep, 50% Ag, 15% CNT 0.03 0.011 33 272 14 35% Ep, 40% CB, 25% NGP 0.03 0.013 45 263 15 35% Ep, 65% GP 0.03 0.011 75 245 16 35% Ep, 55% GP, 10% CF 0.03 0.012 160 211 17 35% Ep, 60% GP, 5% GL 0.03 0.014 220 195 18 35% Ep, 55% GP, 10% CF 0.03 0.012 310 178 19 50% VE, 50% Ag 0.03 0.021 2.3 294 20 50% VE, 40% Ag, 10% NGP 0.03 0.023 4.6 289 21 50% VE, 40% Ag, 10% GNF 0.03 0.024 11 275 22 50% VE, 44% Ag, 1% CNT 0.03 0.023 29 243 23 50% VE, 30% CB, 20% NGP 0.03 0.026 45 222 24 50% VE, 50% GP 0.03 0.023 63 203 25 50% VE, 40% GP, 10% CF 0.03 0.024 88 183 26 50% VE, 45% GP, 5% GL 0.03 0.027 176 140 27 50% VE, 40% GP, 10% CF 0.03 0.024 260 119 28 50% VE, 40% GP, 10% CF 0.03 0.024 320 109 Note: Ep = epoxy, VE = vinyl ester resin, GP = fine graphite particles, NGP = nano graphene plate, CB = carbon black, CF = carbon fiber, GL = glass fiber, GNF = graphitic nano-fiber, Ag = silver nano particles, CNT = carbon nano-tubes.

FIG. 8 further illustrates how the overall conductivity of a three-layer bipolar plate depends upon the ratio of the resin mixture layer (or core layer) thickness to the thickness of a flexible graphite sheet (for Samples 1-9, the set of examples that have the highest resin mixture resistivity). With the core layer resistivity slightly fluctuating between 0.10 and 0.14Ω-cm, a top layer/core layer thickness ratio of approximately 7.5 or higher gives the 3-layer plate a conductivity greater than 100 S/cm. With the top and bottom layer being each 0.3 mm (300 μm) thick, the resin mixture layer is 40 μm or thinner. In order to obtain a bipolar plate conductivity of 200 S/cm, the resin mixture layer has to be lower than 10 μm (further preferably <5 μm). For other two sets of examples (Samples 10-18 and 19-28) given in Table 1, any top layer/core layer ratio from 1/1 to 130/1 is good enough to result in a high bipolar plate conductivity (greater than 100 S/cm). Any ratio greater than 5/1 leads to a plate conductivity greater than 200 S/cm.

These examples have clearly demonstrated the superior electrical conductivity of the presently invented SMC compositions and the SMC-based flow field plate or bipolar plate products. These conductivity values are far superior to those of most of prior art bipolar plates. 

1. A sheet molding compound composition for use as a fuel cell flow field plate or bipolar plate, said composition comprising a top sheet, a bottom sheet, and a resin mixture sandwiched between said top sheet and said bottom sheet, wherein (a) at least one of said top sheet and bottom sheet comprises a flexible graphite sheet; (b) said resin mixture comprises a thermoset resin and a conductive filler present in a sufficient quantity to render said composition electrically conductive enough to be a fuel cell current collector material; and (c) said flexible graphite sheet has a planar outer surface having formed therein a fluid flow channel.
 2. The sheet molding compound composition as defined in claim 1 wherein both said top sheet and bottom sheets are flexible graphite sheets having opposite planar outer surfaces, at least one of said outer surfaces having formed therein a fluid flow channel.
 3. The sheet molding compound composition as defined in claim 2 wherein each of said opposite outer surfaces has formed therein a fluid flow channel.
 4. The sheet molding compound composition as defined in claim 1 wherein said top sheet is a flexible graphite sheet having an outer planar surface having formed therein a fluid flow channel, and said bottom sheet is not a flexible graphite sheet.
 5. The sheet molding compound composition as defined in claim 4 wherein said bottom sheet comprises a carbon paper, carbon or graphite fabric, conductive polymer film, or metal foil.
 6. The sheet molding compound composition as defined in claim 4 wherein said bottom sheet comprises a thermoplastic film which is removed before said flow field plate is incorporated as a fuel cell component.
 7. The sheet molding compound composition as defined in claim 1 wherein said thermoset resin is selected from the group consisting of unsaturated polyester resins, vinyl esters, epoxies, phenolic resins, polyimide resins, bismaleimide resins, polyurethane resins, and combinations thereof.
 8. The sheet molding compound composition as defined in claim 1 wherein said conductive filler comprises a conductive material selected from the group consisting of carbon fibers, metal fibers, carbon nano-tubes, graphitic nano-fibers, nano-scaled graphene plates, carbon blacks, metal particles, and combinations thereof, said conductive material being present in an amount of at least about 3% by weight, based on total weight of said resin mixture.
 9. The sheet molding compound composition as defined in claim 1 further comprising a catalyst, inhibitor and/or a mold release agent.
 10. The sheet molding compound composition as defined in claim 1 wherein said composition has an electrical conductivity no less than 100 S/cm.
 11. The sheet molding compound composition as defined in claim 1, further comprising a coolant channel.
 12. A fuel cell comprising a flow field plate made from a sheet molding compound composition as defined in claim
 1. 13. A fuel cell stack comprising a plurality of fuel cell units separated by at least a bipolar plate made from a sheet molding compound as defined in claim
 3. 14. The flow field plate as defined in claim 1, wherein said resin mixture is approximately 40 μm or thinner.
 15. The flow field plate as defined in claim 1, wherein said resin mixture is approximately 5 μm or thinner.
 16. A sheet molding compound composition, comprising a top sheet, a bottom sheet, and a resin mixture sandwiched between said top sheet and said bottom sheet, wherein (a) said top sheet and/or said bottom sheet comprises a flexible graphite sheet; (b) said resin mixture comprises a thermoset resin and a conductive filler present in a sufficient quantity to render said resin mixture electrically conductive with a bulk conductivity no less than 10 S/cm.
 17. The sheet molding compound composition as defined in claim 16, wherein said conductive filler comprises a conductive material selected from the group consisting of carbon fibers, metal fibers, carbon nano-tubes, graphitic nano-fibers, nano-scaled graphene plates, carbon blacks, metal particles, and combinations thereof, said conductive material being present in an amount of at least about 3% by weight, based on total weight of said resin mixture.
 18. The sheet molding compound composition as defined in claim 16, wherein said resin mixture has a thickness no greater than 1/15 of the sum of a top sheet thickness and a bottom sheet thickness, measured after said composition is cured or molded into a solid product.
 19. The sheet molding compound composition as defined in claim 16, wherein said resin mixture has a conductivity no less than 50 S/cm.
 20. The sheet molding compound composition as defined in claim 16, wherein said composition has an overall conductivity no less than 100 S/cm, measured after said composition is cured or molded into a solid product.
 21. The sheet molding compound composition as defined in claim 16, wherein said composition has an overall conductivity no less than 200 S/cm, measured after said composition is cured or molded into a solid product.
 22. The sheet molding compound composition as defined in claim 16, wherein said composition has an overall conductivity no less than 250 S/cm, measured after said composition is cured or molded into a solid product.
 23. A sheet molding compound composition for use as a fuel cell flow field plate or bipolar plate, said composition comprising a top sheet, a bottom sheet, and a resin mixture sandwiched between said top sheet and said bottom sheet and bonded thereto, wherein (a) each of said top sheet and bottom sheet comprises a flexible conductive material sheet selected from a carbon paper, carbon or graphite fabric, conductive polymer film, or metal foil; (b) said resin mixture comprises a thermoset resin and a conductive filler present in a sufficient quantity to render said composition electrically conductive enough to be a fuel cell current collector material; and (c) said flexible conductive material sheet has a planar outer surface having formed therein a fluid flow channel. 